DE3236874C2 - Ghost signal detection system for a television receiver - Google Patents

Abstract

A television ghost detection system is described which includes a variable delay line for delaying test signal components of the main video signal. The test signal contains color sync signals and can include, for example, the horizontal sync pulse and color sync signals of the lines of the vertical blanking interval which follow the last equalizing pulse interval. The delay of the delay line is changed first until the delayed horizontal sync pulse of the main signal is essentially in temporal coincidence with its ghost horizontal sync pulse at the input of the delay line and the delayed main color sync signal and its ghost echo are essentially temporally coincident. The two color sync signals are then compared with a phase detector, the output signal of which is used as a control signal to regulate the delay of the variable delay line, in such a way that the delayed and undelayed signals are virtually completely coincident.

Description

The invention relates to a ghost signal detector system as it is assumed in the preamble of claim 1 and from DE-OS 27 26 440 is known

In this laid-open specification and in DE-OS 32 227 an arrangement for determining the presence and the temporal position of a television ghost signal with regard to the desired or main television signal is described. With this arrangement a test signal of known properties contained in the demodulated video signal is fed to a variable delay line A ghost signal is then superimposed on this test signal by an echo or a ghost signal. The test signal and his Ghost echoes are repeatedly fed to the adjustable delay line and its delay is changed gradually until it has a value such that the test signal of the main signal leaves the delay line at the same time as the ghost signal enters it. This condition is achieved with the help of a Coincidence detector detected, whereupon the delay line is controlled by a automatic phase control circuit is adopted, which ensures that the time position of the ghost signal is tracked and maintains the state of coincidence. After that, a ghost signal cancellation

circuit using a similar changeable delay line activated to the ghost signal to wipe out. The main delayed signal at the output of the variable delay line of the ghost signal cancellation circuit is inverted to a pseudo ghost signal, which with your the ghost signal containing video signal is summarized in the sense of its erasure. One such cancellation circuit for ghost signals is described in US Pat. No. 4,359,760 (corresponding to DE-OS 3132 253).

The test signal used in the above-described ghost signal detector constitutes a video signal component known properties. Examples of such test signals include the one used during line 266 of the The transition occurring during the vertical blanking interval, the horizontal sync pulses occurring during the vertical blanking interval and specially transmitted pulses which are in unused lines of the vertical blanking interval are inserted, such as sine · square-wave pulses. In the case of line 266 and in the case of the horizontal sync pulses in the vertical blanking interval it has been shown that an automatic reacting to these signals Phase locked loop does not maintain the delay line delay as accurately as it does it would be desirable for the cancellation circuit to completely erase the ghost signal. In particular shall match the delayed main signal with the ghost signal within 200 ns remain, which is approximately the sampling time between two adjacent fluorescent elements of the picture tube a receiver operating on the NTSC television system. The relatively low frequency of transitions these above test signals makes maintaining this accuracy through the automatic Phase locked circuit unreliable.

Based on DE-OS 27 26 440, the task is of the invention in specifying measures that allow more precise adjustment and maintenance allow the delay line so that the ghost echoes over the entire image area are better canceled can be.

This object is achieved by the features specified in the characterizing part of claim 1. Further developments of the invention are characterized in the subclaims.

In accordance with the principles of the invention to be described herein, a ghost signal detection system is in Televisions are provided which have a variable delay line for delaying the test signal components of the main video signal contains The test signal contains burst signals and can, for example the horizontal sync pulses and color sync signals of the lines of the vertical blanking interval which follow the last equalization pulse interval. The delay of the delay line will be first changed to the delayed horizontal sync pulse of the main signal essentially in time coincident with its ghost pulse echo occurs at the input of the delay line and the delayed The main color sync signal is essentially temporally coincident with its ghost echo the two color sync signals are compared by means of a phase detector, the output signal of which is used as a control signal is used to regulate the delay of the variable delay line, such that the delayed and the instantaneous signal can be kept virtually completely coincident.

In the accompanying drawings shows
F i g. 1 shows, in block diagram form, a television ghost signal detector according to the invention;

F i g. 2 shows a detailed embodiment of the circuit for the rough alignment of the test signal from FIG. 1;

F i g. 3 shows in further details an embodiment of the in FIG. 1 included circuit for aligning the burst signal phasing and
ίο F i g. 4 to 8 waveforms to explain the operation of the circuits according to the F s g. 2 and 3.

In the case of the in FIG. 1 circuit of a ghost signal detector a demodulated video signal, on which a ghost signal may be superimposed, becomes the input a gate circuit 10 for lines 10 to 16 is fed. This gate circuit is triggered by gate pulses via the Lines 10 through 16 are opened so that lines 10 through 16 of each field of a video signal pass through can. The strobe pulses for lines 10 to 16 can be obtained from a vertical down counter circuit in a similar manner Way can be derived how the activation signal for the line 10 is derived by a vertical down counter will, as shown in FIG. 3 of the aforementioned US-PS 43 64 092 (SE-OS 31 32 227) is represented by the Lines passed through port 10 are those seven lines of the vertical blanking interval which are immediately follow the second compensation pulse interval, each of these lines contains a horizontal sync pulse, followed by eight to eleven periods of a burst color signal and no video information. The horizontal sync pulses and the burst signal of these lines are in the circuit of FIG. 1 as test signals used.

The signals passed through the gate 10 are fed to the input of a variable delay line 12 and an input of a coincidence detector 14 and a 3.58 MHz filter 31. The changeable one Delay line 12 may, for example, be a charge coupled delay line which is a Contains series of stages clocked in parallel. The CCD delay line illustrated here can for example Contain 120 stages, which are clocked by the signal of a voltage controlled oscillator (VCO) whose frequency can be changed over a range from 8 to 20 MHz. This gives you a Adjustable delay in the range from 6 to 15 μβ. Other combinations of delay line lengths and clock frequencies can be used. For example would make a delay line with 100 so stages running at a clock frequency of 10 to 15 MHz is clocked, result in a variable delay in the range from 6.67 to 10 μβ.

The output of the delay line 12 is connected to the inputs of a clipping circuit 16 and one 3.58 MHz filter 32 connected. The clipping circuit 16 functions in the same way as a synchronizing signal separating circuit and leaves the delayed horizontal sync signals excluding the color sync components lines 10 to 16 through. The output of the clipping circuit 16 is with a connected to the second input of the coincidence detector 14, which generates an output signal when the delayed Main sync signal at an input wholly or partially temporally coincident with the ghost sync signal is at its other entrance. The output of the clipping circuit 16 also has an input a control circuit 22 coupled. The output of the coincidence detector 14 is connected to an input of the re-

5 6

gel circuit 22 and also with the input of a coarse setting circuit at some point a control

Coarse phase detector 35 for the color sync signal gel state, in which the delayed main syn-

coupled. chronsignal at least partially coincident with his,

The outputs of the 3.58 MHz filters 31 and 32 are connected to the ghost sync signal. The coincidence detector 14 then generates a coincidence pulse during the process of the inputs of limiter amplifiers 33 and 34 5. These limiter amplifiers provide amplified coincidence conditions. This coincidence pulse and limited images of the color sync signals have the effect that the coarse phase detector 35 checks the phase relationship between the delayed main color sync signals and the inputs of a signal and the ghost color sync signal sampled phase detector 36, which begins by the sampling pulses io When these two color sync signals by j | for lines 10 to 16 is keyed. The output of the more than one color sync signal period does not match the phase detector 36 is matched via a filter 37, then the coarse setting circuit 20 can the !:. output of a gate circuit 38 connected. The output of the oscillator 18 continue to regulate until there is a match f \ is present at an input of a voltage-controlled OS of the color sync signals. zillators 18. The outputs of the coarse phase detector 35 15 chronsignals once with an accuracy within for the color sync signal are matched with the gate circuit 38 half a period, then the coarse phase detector 35 coupled to the control circuit 22 blocks the control circuit 22 and the

The control circuit 22 are connected to their other input ports 38, so that the control of the oscillator 38 from the {

The Tastimpuis for lines 10 to 16 and color sync signal phase detector 36 were also taken over

the horizontal syn-

chronimpulses supplied. An output of the control circuit to the delay of the delay line 12

with the input of a voltage step generator within half a color sync signal period,

gate 24 coupled, its output to the oscillator 18 or within 140 ns, the time delay

This oscillator provides a clock signal that is used to keep between main and ghost signals. the

Regulation of the delay of the variable delay 25 Delay of the delay line in the ghost

conduction line 12 and the delay of a similar signal cancellation circuit is also controlled by the Si

(not shown) delay line for the signal of the oscillator 18 controlled so that the ghost

star signal cancellation is used. The signal used for this purpose is completely wiped out.

Circuit can be from the in the mentioned US-PS A more detailed embodiment of the Grobein-

43 59 760 (DE-OS 31 32 253) described type. 30 control circuit 20 according to FIG. 1 is in FIG. 2 shown.

The in F i g. The circuit illustrated in Fig. 1 provides horizontal synchronism derived from the video signal.

Star signals arrive during the line intervals 10 to 16 fixed pulse and tactile pulses for lines 10 to 16

and ensures automatic tracking to the inputs of a UN D gate 60, its output

Setting the delay of the delay line with the input of a monostable multivibrator 62]

12, until the main signal is connected by the time interval between 35 The increasing output signal ("1")

Main and ghost signals is delayed The delay of the monostable multivibrator is a reset

tion of the delay line is fed through the oscillator input (R) of an RS flip-flop 66, and that

The output signal (»0«) of the monostable multi-

device 20, which with the stages 22 and 24 visual vibrator 62 is connected to the input of a second monostatic

is light, and through the fine adjustment circuit 30, which 40 two multivibrators 64 fed.

the indicated stages 31 to 38 contains controlled gnal of the monostable multivibrator 64 arrives at a

will. The coarse setting circuit 20 changes the delayed input of an AND gate 72 and to an input

tion of the delay line in stages until the passage of an AND gate 102. The set input (S) of the

hesitated test signals at their output in the approximate R-S flip-flop 66 are those of the coincidence detector 14

wise temporal coincidence (i.e. coincidence pulses generated with an accuracy of 45 according to FIG. 1 are supplied,

The Q output of the flip-flop 66 has an input

corresponding ghost test signals at the input of the AND gate 102 and the Q output of the flip-flop 66

Delay line stand. This coarse setting of the coupled with a second input of the AND gate 72

Both signals are fixed by the coarse phase detector 35. The elements 60 to 66 in FIG. 2 correspond to the then set a fine adjustment of the oscillator 50 control circuit 22 from FIG. 1.

via the control signal generated by the phase detector 36. The output of the AND gate 72 is

causes what is a measure of the phase relationship output of a switched or gated current source 74

connected between the delayed burst of the. If the power source 74 is keyed then iie-

Hauptsignaies and its corresponding ghost color it produces a charging current to a capacitor 76, the Synchronous signal represents 55 between its output and ground is the output

The ghost signal must first be determined by the coarse dividing current source 74 is also connected to the oscillator 18 circuit 20. The control circuit 22 measured F i g. 1 via a resistor 78 and with one can cause the voltage step generator 24 to move the input of a comparison circuit 82 coupled to the parallel oscillator 18 over its entire frequency range IeI to the capacitor 76, which is normally open in steps. The oscillator frequency 60 and switch 80. A second input of the comparison is supplied by circuit 20 during each field on circuit 82 with a reference voltage V _M which changes the end of each of lines 10 to 16 to when the output of comparison circuit 82 is with a, no ghost signal it is determined what by the input of a monostable multivibrator 84 connection of a coincidence pulse through the coincidence whose "0" output is expressed at a third input of the denzdetektor 14, then the 65 AND gate 72 is connected and moves whose »!« - off switch continues to let the oscillator continue to run a control signal via its frequency response to close the normally rich. open switch 80 provides elements 72 to 84

if a ghost signal is present, then they together form a setting circuit 70 for the _f "

incremental delay for controlling the delay time of the variable delay line 12 by controlling the oscillator 18 accordingly.

The output of AND gate 102 provides a control signal to close a normally open Switch 112, which is in series with the normally open Switch 108 and a resistor 114 between the output of an early / late gate pulse generator 104 and an input of the oscillator 18 is located. The gate pulse generator 104 works essentially as follows as described in U.S. Patent Application No. 230,310 filed Jan. 30, 1981 and triggered by the delayed horizontal sync pulses generated by the clipping circuit 16 of FIG. 1 can be delivered. The switch 108 is when a coincidence pulse supplied by the coincidence detector 14 occurs opened. A capacitor UO is connected to ground from the connection point of switches 108 and 112. the Elements 102 through 114 of FIG. 2 together form one Coincidence setting circuit 100.

A more detailed illustration of the fine adjustment circuit 30 from FIG. 1 is in FIG. 3 shown. The already in connection with F i g. 1 mentioned circuit elements are shown in FIG. 3 denoted by the same reference numerals. The output of the coincidence detector 14 is coupled to the input of a monostable multivibrator 40, the “1” output of which is coupled to the reset inputs (R) of two counters 46 and 48 and to the input of an inverter 52. The amplified and limited ghost color sync signal, which is supplied by the limiter amplifier 33, is fed to an input of an AND gate 42 and the amplified and limited delayed main color sync signal is fed from the limiter amplifier 34 to an input of a NAND gate 44. The limiter amplifier 33 also supplies an amplified one Ghost color sync signal Gb to the phase detector 36, and the limiter amplifier 34 supplies an amplified, delayed main color sync signal Mean the phase detector 36. The output of the AND gate 42 is connected to the signal input of a counter 46 and the output of the NAND gate 44 is connected to the signal input of a counter 48 .

The counters 46 and 48 can be 3-bit counters whose output signals correspond to count values 1, 2 and 4. The 1, 2 and 4 outputs of the counter 46 are connected to inputs of an AND gate 7, and the 1, 2 and 4 outputs of the counter 48 are connected to inputs of a NAND gate 50. The output of the NAND gate 50 is connected to corresponding inputs of gate circuits 42 and 44, and the output of the NAND gate 7 is connected to the data input D of a D flip-flop 54. The clock input (C) of the flip-flop 54 is coupled to the output of an inverter 54. The Q output of the flip-flop 54 is connected to a second input of the NAND gate 102 from FIG Activation input of gate 38 connected. The elements 40 to 54 from FIG. 3 together correspond to the coarse phase detector 35 for the color sync signal according to FIG. 1.

The mode of operation of the circuit according to FIG. 2 is based on the in the F i g. 4 and 5 illustrated waveforms F i g. 4a shows the signals from three of the lines of the vertical blanking interval, which follow the second equalization pulse interval, i.e. lines 10, 11 and 12. Each of these lines contains a horizontal sync pulse (120, 120 ', 120 ") followed by a color sync signal. The sync pulses 120, 120' and 120 "are separated from the incoming video signal and fed to the AND gate 60, which also receives activation strobe pulses for lines 10 to 16 at the same time. The output signal of the AND gate 60 goes over to a high value in response to each sync pulse, and the monostable multivibrator 62 is thus triggered to generate pulses 122, as can be seen from FIG. Ib can be seen. The leading edge of pulse 122 resets flip-flop 66, the Q output of which disables coincidence setting circuit 100, while its high Q output activates incremental delay setting circuit 70. At the end of the pulse 122, the "O" output signal of the monostable multivibrator 62 triggers the monostable multivibrator 64, which then generates a pulse 123 which is shown in FIG. 4b and occupies a time interval from U to is. The pulse 123 passes through the AND gate 72 and samples the current source 74, which charges the capacitor 76 during the time interval u to is. This increases the voltage of capacitor 76, as shown by waveform 124 in FIG. 4d shows in this way the frequency of the oscillator 18, and thus the delay of the delay line 12, is changed step-by-step. A typical increase in delay would be, for example, a microsecond. For the purpose of illustration, it is assumed here that a low control voltage for the oscillator results in a high frequency signal and thus a short delay in the delay line, while a high control voltage results in a low frequency signal and thus a long delay in the delay line. It can thus be seen that if no ghost signal is detected, the incremental delay adjustment circuit increases the delay line delay from a minimum delay value in microsecond increments during each of lines 10 through 16 over several television fields to a maximum delay value. If the voltage on the capacitor 76 exceeds its maximum value Vm , which corresponds to the maximum desired delay of the delay line, then the comparison circuit 82 delivers an output pulse to trigger the monostable multivibrator 84. The signal from the "0" output of the monostable multivibrator 84 has the AND Gate 72 blocked to switch off the current source 74, and the 1 output signal of the monostable multivibrator 84 closes the switch 80 to discharge the capacitor 74. The circuit 70 is then in a state in which the delay line 12 can run through its delay range again.

The pulse 122 generated by the monostable multivibrator should not be longer than the maximum delay time of delay line 12 plus about 11 us, since the effect of this pulse is to prevent any changes in oscillator frequency and delay until the main sync signals and burst signals have traversed delay line 12. The one from the monostable multivibrator 64 generated pulse 123 should have a length at which the capacitor 76 by one step charged according to the voltage control characteristic of the oscillator is selected The pulse generated by the monostable multivibrator 84 should be sufficient be long to discharge capacitor 76, in any case it should be longer than the duration of the pulse 123 be.

9 10

If the video signal has a signal within the range of the voltage waveform 146 in FIG. 5e again delay line delayed ghost signal is overloaded- if this voltage level is applied to the oscillator at time U , then the setting circuit for the zillator input, when the switch 112 is gradually delayed soon, causes the length of the lock to be closed. This will increase the oscillator frequency delay line close to the delay between 5 speaking and the delay of the delay main and ghost signals coming up, and then decrease line 12 so that the pulses 130 will generate a coincidence pulse, one in this case and 132 'better for coincidence to be brought,
typical signal state is shown in FIGS. 4e and 4f a typical sequence of detection (shown by oeister, where the waveform 130 according to FIG. 2 and delayed main signal can occur at the output of the delay 10 3 illustrated arrangement is in approximately line 12 and the waveform 132 the ghost figure. 7 illustrates At the beginning of the sequence it is indicated at the input of the delay line. The assumption that the oscillator frequency is high (i.e. the waveforms 4e to 4 / are discharged on the same time scale - capacitor 76 is discharged), so that the delay is drawn, and you can see that the synchronization pulses 130 of the delay line is shorter than the delay and 132 is during the hatched interval h to h of the 15 between the main and ghost signal. In this case, pulses 132 are coincident. During the time interval, the delayed variable h to r ₃ illustrated in FIG. 7b appears, a coincidence pulse is generated which sets the main signal at the output of the variable delay of the flip-flop 66. This then blocks the setting line 12 before it is shown in FIG. 7b illustrated circuit 70, which holds the voltage at the capacitor 76 ghost signal to the input of the delay line at its instantaneous value. The flip-flop 66 is activated. (The main signal has a larger fourth also the coincidence setting circuit 100 over amplitude than its ghost echo, but it is easier to activate the AND gate 1OZ Fig.4f ghost signal drawn in Fig.7) The delayed is shown as a result of each main signal from the clipping circuit according to Fig. 7. 7a consists of a Horizon-16 delivered delayed sync pulse 130. The 25th valley sync pulse 150, which ends at time h , and early / late gate pulse consists of a positively directed color sync signal 152 which follows in time half 134 and a negatively directed half 136. Interval fo to r _t occurs The ghost signal according to FIG. Tc If the switch 108 is closed, then loads or contains a sync pulse 154.
the early / late gate pulse discharges the capacitor HO. Since the sync pulses 150 and 154 are not timed when the resistors 78 and 114 are coincident at the same input 30, the setting circuit 70 for the output connection of the oscillator 18 is connected, gradually delaying the oscillator control voltage then the capacitor 110 is set to the same value as gradually and thus reduces the oscillator frequency of the capacitor 76 charged when the AND gate and increases the delay of the delay line 102 the switch 112 as a result of the pulse 123 of the monitor 12. When the gate circuit 10 closes the next of the time stable multivibrator 64 35 len 10 to 16 get to the delay line, the early / late gate impulse lets this charge value, which then rushes the delayed main signal to the ghost signal is then fed to the oscillator input if it is a shorter length ahead, as indicated by switch 112 on pulse 123 closed again the temporal position of the ghost signal 1 56 in FIG. 7c. The capacitors then equal each other with regard to the delayed main signal according to FIG. 7a shows a new voltage level in order to recognize the oscillator frequency 40. The setting circuit for the step-by-step and thus the delay of the delay line 12 then increases the voltage on the delay line again. Capacitor 76.

For the by the temporal position of the pulses 130 and After some several of the lines 10 to 16 through 132 according to FIGS. 4e and 4f, the delay line has passed through the delay line, the part 45 lying in the interval ii to t ₂ is the delayed main signal and the undelayed early / late gate pulse 134 to the capacitor 110 ghost signal which is shown in FIGS. 7a and 7d, as indicated by pulse 138 in FIG. 4h ten relative temporal positions. It can be seen that at is shown The coincidence pulse opens the switch these temporal relationships of the main syncronism-108 during the interval f ₂ to I ₃ . The voltage at pulse 150 and its ghost sync pulse 158 just before capacitor 110 will then partially coincide in time during the interval (1 to so at point in time ti . At this point in time, a coincidence signal is generated, as shown in voltage curve 140 The oscillator frequency is lowered, the flip-flop 66 sets and the control of the delay, and the delay of the delay line rang the delay line on the Koir.zidcr.zein is increased to allow the pulses 130 and 132 to pass better to the control circuit 100. The coincidence signal bring coincidence 55 also triggers the monostable multivibrator 40, the

When the delayed main signal 130 and the game in FIG. Pulse 180 shown in Figure 7e generates Solange

stersignal 132 'occurs in the relative temporal positions of the pulse 180, the counters 46 and 48 are

are located, as shown in FIGS. 5a and 5b illustrate not reset and can change their signal inputs

then the sync pulses are coincident during the inter- gen from the limiter amplifiers 33 and 34 over the range fc to t _7. The switch 108 will count the pulses supplied during gate circuits 42 and 44,

This interval is opened, and only that part of the limiter amplifiers 33 and 34 produce amplified

Early / late gate pulse 134, 136 according to FIG. 5c, the selected and limited signals when the burst signals

rend of the interval fc to ti occurs, the condensate reaches the filter 31 and 32 respectively. These fiI-

Sator HO, as indicated by the signals supplied by parts 142 and 144 of the system are illustrated in FIG.

Early / late gate pulse in FIG. 5d, 65 is light and includes a horizontal sync pulse 190

The effect of the pulse sections 142 and 144 and a color sync signal 192. The color sync signal

it says that the capacitor 110 has a frequency of about 3.58 MHz (in the NTSC-

ren voltage level is discharged as is done by the system) and extends over eight to eleven periods.

The color sync signal 192 passes through the filters to the limiter amplifiers, which thereupon the in F i g. Generate pulse shapes 194 shown in Figure 6b. The nine-period color sync signal 192 thus generates nine pulses of signal 194.

The pulse train 194 of the burst signal resulting from the burst signal 192 according to FIG. 7a has been derived is inverted by the NAND gate 44 and supplied to the counter 48. Because of the signal inversion, the falling edges of the impulses clock again F i g. 6b the counter which at time ii a count value 7 reached This count value 7 is determined by the NAND gate 50 and leaves the output signal of this gate go low, whereby the gates 42 and 44 are blocked against the passage of further pulses. if the gate 42 is locked in this way, then the Impui & Zug of the color sync signal, which from Color sync signal 159 of the ghost signal according to FIG. 7d has been derived, the counter 46 does not reach. At the end of the pulse 180 of the monostable multivibrator, the counters are reset again. Towards the end of the line, the oscillator frequency is reduced again, this time under the control of the Early / late gate signal from coincidence setting circuit 100.

During the passage of a few more lines 10 to 16, the delayed main signal becomes with the ghost signal brought into temporal coincidence even better by the coincidence setting circuit 100, like this for ghost signals 160, 162 and 164 of FIG. 7f to 7h compared to the main signal according to FIG. 7a illustrates is. During each of these lines, the counter 48 counts seven of those derived from the main color burst Impulses. In the case of the FIGS. 7f and 7g, the counter 46 does not receive any pulses, however, ghost color sync pulses of the waveform shown in Fig. 7h begins to count.

A typical pulse train 200 derived from the delayed main color sync signal 152 shown in FIG. 7a is derived is shown in FIG. 8a illustrates one from the ghost color sync signal 166 of FIG. Typical pulse train 202 derived 7h is shown in FIG. 8b shown. The first seven pulses of the pulse train 200 are _{counted by the counter 48 during the interval f 0} to ii, and the pulses of the ghost pulse train 202 are counted by the counter 46 during the interval 6 to ti is supplied, the counter 46 increases its count on the leading edges of the ghost pulse train. At time ii, the gates 42 and 44 are blocked by the signal from gate 50 and the counters are stopped, the counter 46 holding a count value 1. When the pulse generated by the moiiöstabiien multivibrator 40 ends, the counters are reset again of the delay line is increased again under the control of the coincidence setting circuit 100

After a few more lines 10 to 16 have passed through the system, the signals at the input and output of the delay line 12 assume the positions in time which are indicated by the signal shapes in FIG. 7i and 7a are illustrated. The counter 48 again counts seven pulses during the period ίο to fi and the counter 46 counts the pulses derived from the ghost color sync signal 170 in the interval U to ii, as shown in FIGS. 8a and 8c shown The ghost Farbsynchronsignalimpulszug 204 according 8c contains five pulses during the time interval U to ti, and the counter 46 holds a count of 5 when the counter 48 reaches its count value 7 The counters are at the end of the monostable Multivibrator 40 generated pulse is again reset, and the coincidence setting circuit 100 in turn brings the delayed and undelayed signals even better into temporal coincidence.

If one or more lines 10 to 16 have passed through the system, then the signals at the input and output of the delay line 12 are in the time positions which the FIG. Figures 7j and 7a show. The coincidence detector 14 generates a coincidence pulse during the hatched area of the ghost sync pulse 172 in FIG. 7j, namely in the interval fe to ti. During the interval ίο to t \, the counter 48 counts the first seven pulses of the main color sync signal pulse train 200 from FIG. 8a, and during the interval t _s to fi, the counter counts 46 pulses of the first seven ghosts color burst signal pulse train 206 to F i g. 8d. If the counter 46 reaches a count value 7, then the output signal of the gate 7 assumes a high value, as indicated by the pulse 182 in FIG. 8f is illustrated. At time ii, the counters stop counting, with both counters taking a count of 7. The gate 7 is now in a state where it supplies a high level signal to the D input of the flip-flop 54. When the pulse 180 'generated by the monostable multivibrator 40 changes to a low level, as in the F i ». 7k and 8e, the signal from the output of inverter 52 clocks flip-flop 54 into its set or set state when counters 46 and 48 are reset. The Q output of flip-flop 54 goes low at this point and blocks gate 102 of FIG. 2, so that the coincidence adjustment circuit 100 no longer affects the oscillator frequency. The Q output of the flip-flop 54 goes high as indicated by the curve form 184 in FIG. 8g shows, and thereby the gate 38 is locked.

The oscillator frequency and the delay of the delay line are now determined by the signal generated by the phase detector 36 on the basis of a phase comparison between the signals Gb and Mb. From the F i g. 8a and 8d it can be seen that when the two counters are stopped at a count of 7, the two bursts are within plus or minus half a period of complete coincidence. The fine adjustment circuit 30 now brings ghost and main signals into complete temporal coincidence at the input and output of the delay line by a phase comparison of the respective color sync signals Gb and Mb-

If the delay in the delay solving is too great, then the counter 46 reaches a count of 8 or more before the counter 48 reaches a count of 7. In this case, the flip-flop 54 is not set because the output signal of the AND gate 7 is at the end of the pulse from the monostable multivibrator 40 goes low and the coincidence adjustment circuit 100 continues to control the oscillator and delay the delay line to bring the main and ghost pulses back into more complete coincidence.
The circuit according to FIGS. 2 and 3 can be used to advantage in a variety of delay line designs. For example, the delay line can be a tapped delay line with an addressable length and an oscillator-controlled

13 14

changeable delay line includes the from the Setting circuit 70 for the output signal generated in steps of delay can be used to control a multiplexer and / or counter, which one the taps of the delay line that differ, for example, in terms of time by 4 µs. The signals for lines 10 to 16 can be delayed by the tapped delay line in multiples of 4 microseconds until a partial coincidence of the sync signals is reached, and then the oscillator controlled delay line would provide the main signal delay under control of the The coincidence adjustment circuit 100 and the fine adjustment circuit 30 increase or decrease in size. The main signal would then be due to the accumulated delays both the tapped delay line and the oscillator controlled delay line can be delayed. In this embodiment, the ghost detection circuit could virtually detect a ghost signal via the search for a full line, and the oscillator-controlled delay line only needed to have a small variable delay range of about 5 µs.

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Claims (7)

Patent claims: 1. Ghost signal detection system for a television receiver with a source of video signals, des nen ghost signals are superseded and which have a signal interval suitable for use as a test signal interval and a synchronous signal component included, with a changeable delay line (12), the signal input of which is output circuit (10) video signals are fed and which is coupled to a control circuit (18), to determine the signal delay effective between the signal input and the signal output of the delay line, and with a tracking circuit (14, 35) whose inputs are connected to the signal input and signal output of the delay line (12) and whose output is coupled to the control circuit (18), characterized in that the video signals Ie are fed to the delay line (12) as color video signals during the test signal intervals and the tracking circuit (14,35) to the Appearance of a delayed color sync signal at the output of the delay line during the Test signal interval and the appearance of any ghost echoes of the color sync signal responds at the input of the delay line, and that the inputs of a phase detector with the signal input and output of the delay line (35) are coupled to derive a control signal, which is a measure of the phase relationship between the delayed color sync signal at the output and its ghost echo at the input of the delay line and via a coupling circuit (38, 22, 24) is fed to the control circuit (18) for controlling the signal delay. 2. System according to claim 1, characterized in that the tracking & circuit means (14) for their activation during states contains practically temporal coincidence of the appearance of the color sync signal at the output of the delay line (12) and its ghost echo at the input of the delay line 3. System according to claim 2, characterized in that the control signal via a coupling circuit (38, 22, 24) of the control circuit (18) is then supplied when the delayed color sync signal and its ghost echo at the output or input of the delay line (12) with an accuracy within half of a burst are fully coincident, and that the system continues to have one a delay setting circuit (20) coupled device (35, 22) for blocking its operation when the delayed color synchro gnal and its ghost echo at the output or input of the delay line with an accuracy within one color sync signal period are coincident. 4. System according to claim 2 or 3, characterized in that the test signal interval is a for Use as a test signal contains suitable signal, and that the system continues a second Tracking circuit (31-38) contains the inputs with input and output of the changeable Delay line (12) are coupled and the output of which is coupled to the control circuit (18) and the appearance of a delayed test signal at the output of the delay line and on the appearance of a possible ghost echo of the test signal at the input of the delay line responds and controls it so that the delay between its input and output is approximately equal to the delay between the test signal and its ghost signal 5. System according to claim 4, characterized in that the second tracking circuit a Coincidence detector (14), the inputs of which are coupled to the input and output of the variable delay line (12) and which the coincident occurrence of a delayed test signal on Output of the delay line and its ghost signal at the input of the delay line and a delay adjustment circuit (20) interposed between the coincidence detector (14) and the control circuit (18) is coupled and at intervals between the application of the test signals to the delay line (12) whose delay changed gradually until the delayed The test signal and its ghost echo appear in approximately full coincidence at the output or input of the delay line. 6. System according to one of the preceding claims, characterized in that the test signal interval in the vertical blanking interval comprises a horizontal line interval with a horizontal synchronization signal suitable as a test signal, and that the input circuit has a circuit (10) for supplying the video signal including the horizontal synchronizing signal and the color synchronizing signal to the input of the delay line during the horizontal line interval of the vertical blanking interval 7. System according to any one of the preceding claims, characterized in that the control circuit comprises a voltage-controlled oscillator (18)